DE4032067A1 - MANAGEMENT DEVICE FOR COMPENSATING Crosstalk - Google Patents

Abstract

A line device, preferably a line terminating device (LE) of a communication system which contains transmitting and receiving circuits (S1, S2, SN; E1) to which transmitting lines (SL1, SL2, SLN) and receiving lines (EL1) are connected, contains at least one receiving circuit (E1) comprising a circuit arrangement (KS) for compensating for crosstalk. A single circuit arrangement (KS) compensates for the crosstalk from several transmitting lines (S1, S2, SN) to one receiving line (EL1). For the compensation, a reference signal (R(1)1, R(1)2, R(1)N) of the transmitting signal is branched off from each transmitting circuit (S1, S2, SN) and a compensation signal (K1, K2, KN) is simulated by an adaptive filter (F1, F2, FN). The individual compensation signals are additively mixed with the receiving signal via subtraction inputs of a subtraction circuit (S). A part of the output signal of the subtraction signal (S) is supplied to the control signal inputs (RS1, RS2, RSN) of the adaptive filters (F1, F2, FN), the other part is processed further to become the receiving signal (DA1). <IMAGE>

Description

The invention relates to a circuit arrangement for compensation of crosstalk in a digital communication system in the area of a line facility with transmission and Receiving circuits according to claim 1. The features that differ on the compensation of crosstalk from one transmit to one Receive circuit for a subscriber are from DE 33 43 584 A1 discloses the features that relate to the compensation of Crosstalk from transmit circuits to receive circuits referring to different participants are new.

For wired, electrical communication the signal transmission takes place partly via pairs of conductors are sometimes combined in a cable. Doing so with a 4-wire transmission, the forward and return lines in one and the same cable, if not in one Star quad arrangement within the cable. Depending on Such a cable has a large number of participants Number of transmission lines due to the cable structure are disturbed by crosstalk. These disorders affect the transmission of messages and can in particular at Transmission of signals between data processing devices too Cause errors in the signal content.  

A well-known way to suppress crosstalk in the cable is now only a part of the lines for transmission use and / or try the cables in a cable to be proven in such a way that minimal crosstalk occurs.

These procedures are very complex and do not lead systematically to suppress crosstalk.

To compensate for crosstalk between the back and forth Returning a subscriber is one from DE 33 43 584 A1 Circuit known. In the known circuit, the Transmitted signal branched part and via an adaptive filter and an inverter obtained a compensation signal and the Received signal of the subscriber.

This known circuit has the disadvantage that it is only that Crosstalk between the forward and return lines of one related transmitting and receiving device, which for bi-directional message transmission is provided can compensate.

The invention is based on the object Circuit arrangement to create the disturbing crosstalk a transmission cable between more than two lines at least partially suppressed.

This object is solved by the features of claim 1.

An advantage of the invention is that the number of used Lines in a transmission cable can be increased because none Blind lines for crosstalk suppression are needed more.

Further embodiments of the invention are the remaining claims and the rest of the description.  

Three embodiments of the invention are partly based on the two figures described below. It shows

Fig. 1, the line device according to the invention of a first embodiment and

Fig. 2 shows a second, supplemented embodiment.

In Fig. 1 is a line terminating equipment LE is a digital communication system for several subscriber, mapped to a circuit CS for the compensation of crosstalk and hint of a transmission cable K. In the left half of FIG. 1, three transmission circuits S ₁ , S ₂ , S _N are shown at the top, representing N transmission circuits, and in the lower half of the figure, a reception circuit E _{1 is} representative of M reception circuits. The number N of transmission circuits S ₁ to S _N and that of the number M of reception circuits E ₁ to E _M are generally not the same due to the different types of subscribers. The transmission cable K is indicated on the right edge of FIG. 1. The transmission circuits S ₁ to S _N are connected to 2-wire transmission lines SL ₁ to SL _N and the reception circuits b to 2-wire reception lines EL ₁ to EL _N belonging to the transmission cable K. The connections R _{(1) 1} , R _{(1) 2} , R _{(1) N} , between the transmission circuits S ₁ to S _N and the reception circuit E ₁ are representative of the connections between the transmission circuits S ₁ to S _N with the reception circuit E. ₁ and are referred to below as reference line R _{(1) 1} corresponding to the two other connections shown reference lines R _{(1) 2} and R _{(1) N.} The signals present on the reference lines are referred to as reference signals and have the same reference numerals as the corresponding reference lines.

The receiving circuit E ₁ includes a number of transmission circuits S _1, S _2, S _N corresponding number of adaptive filters F _1, F _2, F _N, whose signal inputs R _1, R _2, R _N, respectively on the corresponding reference line R ( _{1) 1} , R _{(1) 2} , R _{(1) N are} connected to a transmission circuit S ₁ , S ₂ , S _N. The signal outputs K ₁ , K ₂ , K _{N of} the filters F ₁ to F _N are each connected to a subtraction input of a subtraction circuit S. The reception line EL _{1 is present} at an N + 1st input, an adder input of the subtraction circuit S. The output of the subtraction circuit S is connected by a control signal connection RSV to the control signal inputs RS ₁ , RS ₂ RS _{N of} the adaptive filters F ₁ to F _N and at the same time leads to the data output DA ₁ via a device processing the output signal.

To indicate which point within a transmission circuit, via the above reference lines with which points the Receiving circuit is connected, each transmission circuit is as follows broken down:

In a first part CV there is a coder and a scrambler and in a second part L the rest of the Necessary message transmission components here as Performance equipment L are referred to.

In addition to the components already described, the receiving circuit E ₁ contains an analog / digital converter AD, a band-limiting filter BF, an equalizer and a decision maker, which are located in a part EE, a descrambler and a decoder, which are located in a part ED are located. In the receiving circuit E ₁ , the compensation signals are fed to the received signal at a corresponding point. In the first embodiment, this means that the received signal, before it is fed to the adding input of the subtraction circuit S, is digitized and has passed through the band-limiting filter. The output of the subtraction circuit S is connected to the data output DA ₁ via the equalizer and decision maker (part EE) and the descrambler and decoder (part ED).

The reference signals R _{(1) 1} , R _{(1) 2} , R _{(1) N} branched off from the transmitting circuits S ₁ , S ₂ , S _N , are each used as the adaptive filters F ₁ , F ₂ , F _{N of} the receiving circuit E ₁ Input signal supplied. In the adaptive filter F ₁ , the crosstalk from the signal line SL ₁ to the receive line EL ₁ , insofar as it originates from the transmission circuit S ₁ , is simulated. The simulated signal, here called a compensation signal, is fed to a subtraction input of the subtraction circuit S and in this way compensates for the crosstalk from the transmission line SL ₁ to the reception line EL ₁ . The control takes place by feeding back the output signal of the subtraction circuit S via the control signal connection RSV to the adaptive filter F ₁ . This simulation is carried out in a known manner by adaptively setting the filter coefficients. The coefficients are determined using the known algorithms. The requirement for setting the coefficients is to minimize the control signal. Such setting of the filter coefficients is in principle z. B. from DE 31 20 434 A1 or from the IEEE Journal on Selected Areas in Communications, Vol. SAC-4, No. 8, November 1986, pages 1337 to 1349 and is therefore not discussed in further detail.

The crosstalk is compensated for from the other transmission lines SL ₂ to SL _N to the reception line EL _{1 of} the reception circuit E ₁ in the same way as described above for the transmission line SL ₁ .

Since the crosstalk also depends on the power level of the Transmission signal depends, and the lines between one Line terminal equipment and an apron device as a rule  have a very strong damping, crosstalk is mainly generated in the vicinity of the line end devices.

A targeted suppression of the effect of the crosstalk is over for this reason in the vicinity of a line end device from special meaning. The circuit arrangement KS for compensation crosstalk therefore makes sense as part of one Line terminal device LE formed. You can use this way the line terminal device LE integrated and therefore very can be realized inexpensively. Even if the connections that with the circuit arrangement KS to compensate for crosstalk this integration on the connections of a line terminal is certainly the largest proportion of Crosstalk is compensated for as there is usually only one per house Line terminal device LE is present and crosstalk with Transmission lines of other participants at the earliest from the next Cable junction, e.g. B. on the street or from the next Apron setup can be done.

But it is quite conceivable that not all transmission circuits are one Line terminal device LE with one or even all Receive circuits of the line terminal device LE through the Circuit arrangement KS for compensating crosstalk are interconnected. The circuit arrangement KS can also used to cross talk between lines to compensate for various line end devices in which Reference lines arranged between the line end devices the compensation takes place as described above.

The circuit KS can be in the range of Line terminal equipment also in the area of others Line facilities such. B. one Arrange the line interface device.  

Furthermore, it is not possible to use the circuit arrangement KS on a line device of a message transmission system limited, but can also be used in a Private branch exchange or a computer system with several Workplaces, wherever there is annoying crosstalk can be seen between several lines.

The first embodiment is limited to the compensation of crosstalk caused by transmission circuits, since this is the main interference as described above. In a second exemplary embodiment, which is shown in FIG. 2, the circuit arrangement KS for compensating crosstalk, as an extension to the embodiment described in the first exemplary embodiment, has a connection of the receiving circuit E ₁ to a second receiving circuit E ₂ . The receiving circuit E ₂ is only shown schematically, it contains the same elements as the receiving circuit E ₁ and, like the receiving circuit E _{1, is} connected to the transmitting circuits S ₁ , S ₂ , S _N via reference lines (not shown). From the received signal of the second receiving circuit E ₂ , a receiving reference signal R _{(1) E is} branched off before the subtraction circuit S (not shown) and fed to the first receiving circuit E ₁ , like the reference signals R _{(1) 0} to R _{(1) N,} and via a additional filter F _E processed accordingly, so that an additional compensation signal K _E arises. In this way, the crosstalk from the receiving line EL _{2 of} the second receiving circuit E ₂ to the receiving line EL _{1 of} the first receiving circuit E _{1 is also} compensated. This is e.g. B. to be recommended if the second receive line EL _{2 is} intended for transmission with a bit rate of 2 Mbit / s or generally disturbing crosstalk from the receive line EL ₂ to the first receive line EL _{1 is} to be expected. If it is expedient, the crosstalk from further reception lines can be compensated in the same way.

The circuit arrangement KS for compensating crosstalk allows for transmission cables where lines are not used Transmission, but to suppress crosstalk were used to use these for transmission. It also allows two lines for transmission with a bit rate of 2 Mbit / s in a transmission cable can be arranged closely adjacent without disturbing Crosstalk arises between these two lines.

A third embodiment (not shown) faces the first two embodiments, an additional Device for compensation of impulse interference. Such Impulse interference can be both from the outside in a transmission cable as well as lines within a transmission cable other lines work. You can therefore only conditionally Crosstalk compensation devices are compensated.

A reference line is available to compensate for impulse interference a converter connected to the receive line. Now occurs in Cable impulse interference, this is both in the Reference line as well as in the receive line equally induced. The one obtained from the reference line Reference impulse disturbance is over the converter Subtraction input of a subtraction element of the receive line supplied and compensates for the impulse disturbance there.

In the simplest case, the converter can be made from a single piece of line exist, advantageously has an adaptive filter for generation a simulation signal.

One in the transmission cable can be used as a reference line Dummy cable can be used. Instead of the blind line, a Transmission line or one of the reception lines other than An additional measure is used for the reference line  Compensation of the transmission signal present on these lines or Receive signal required. For this, the send or Receive signal via an adaptive filter in a known manner simulated and then in a known manner from the signal subtracted, and from it the compensation signal for suppression is obtained from impulse disturbances.

Claims (7)

1. Line device, preferably a line end device (LE) of a message transmission system, which contains transmission and reception circuits (S _i , i = 1, 2, ..., N; E _j , j = 1, 2, ..., M) , are connected to the transmission lines (SL _i , i = 1, 2, ..., N) with the following features:

• at least one receiving circuit (E _j ) contains a circuit arrangement (KS) for compensating crosstalk,
• - A plurality of transmit circuits (S _i ) each enter at least one receive circuit (E ₁ ) with a circuit arrangement (KS) for compensating crosstalk, reference signal (R ( _{1) i} , i = 1, branched off from the transmit signal to be generated by them ₎ , 2, ..., N) off,
• - Each circuit arrangement (KS) for compensating crosstalk contains an adaptive filter (F _i ) for each reference signal (R _{(1) i} ), which uses the reference signals (R _{(1) i} ) to produce a compensation signal (K _i , i = 1, 2, ..., N), and a subtraction circuit (S) which subtracts the sum of the compensation signals (K _i ) from the received signal of the receiving circuit (E ₁ ) and whose output signal is the control signal of the adaptive filter (F _i , i = 1 , 2, ..., N) and the output signal (DA ₁ ) of the receiving circuit (E ₁ ) is further processed.

2. Line device according to claim 1, characterized in that at least one second receiving circuit (E ₂ ) for at least one receiving circuit (E ₁ ) with a circuit arrangement (KS) for compensating for crosstalk, from which received signal received by it, reference signal (R _{(1) N + 1} ) outputs. 3. Line device according to one of claims 1 or 2, characterized in that, in the event that its transmission and reception lines (S _i , E _j ) are guided in a transmission cable together with transmission and reception lines, other line devices, at least with them part of these line devices and at least part of the transmission and reception circuits contained therein is connected via the circuit arrangement (KS) for compensating crosstalk. 4. Line device according to one of claims 1 to 3, characterized in that at least two transmitting and / or receiving circuits (S _i , E _j ) are available for a bit repetition frequency of at least 2 Mbit / s. 5. Line device according to one of claims 1 to 4, characterized characterized in that the adaptive filters are transversal filters and each have a maximum of five coefficients. 6. Line device according to one of claims 1 to 5, characterized in

• - That the receiving line (EL ₁ ) is connected via a converter to a referral line (SL ₁ ),
• - That the reference line (SL ₁ ) and the receiving line (EL ₁ ) in a transmission cable (K) are arranged so closely adjacent that an occurring pulse disturbance is approximately equally induced in them, and
• - That a compensation signal for suppressing the pulse interference in the receiving line (EL ₁ ) on the receiving line (EL ₁ ) is performed via the converter.

7. Line device according to claim 6, characterized in that that the converter uses an adaptive filter to simulate the Has impulse disturbance.